DE1400957A1 - Hydraulic fluid storage - Google Patents

Description

With the invention refer to lean and d nbee = d * rs a, Pressure medium bsw. . aohw i ar » ade lean = . The promising "US aaskaaohs le ntealdung is stubborn tuaatsamnachricht to the boxes of elareos 3. Adam at 1g. Wiesenher "g slsreichtn i4gr, 'M1 326e X d, t.der Besetebn = g ePlutd 7earing ",, die nzwiaohen urüokge- seam In sing riebe rteaa from under Asgendruoh ehden rsdieles got to store. However, this and that the fieabnaat- sfehendea raäfsl, camp la vtuler M »toht Bvaobränkmoen Subjected. ouch l agsr sind et liit t .eaga- n akrän ken der gtrögen, tohttelg en der tro b eräahs vsrm eh en e st * this der Y eet «t 2 929 5ran 4iku et btaohrleben In * "la diessac Croohr et al-Utt finds: the gustraa the pressure means of one and half the empty lying point by a limited reserve of supply lanale for the pressure medium on an inner chamber statu in which practically no Druskabgll through the flow mcacl, ttels appears through the room. The Druakntteletrom at. the other end of the Orewks st a1. lager goes from the chamber, in the practically no. ekahiaall by pouring that Pressure occurs., And there = limited by another Area the gtröaungrkanal.e for the pressure medium. Eu exists * eaait only * Yes limited Bersiob den gtr ü »Mo ketascloe for the Dx u o kx ittel to store the Crecke et a1 at each end, To write in a D ruakditäereae , dat Radialbeläst # megen aafhebssn came. If the Croka stops working to "m uence hence the gei®cheura> m between" r wool and Housing in the limited area, to J * de; Bath one of these store 0.0'7i2 am (C, 005 target) or very much, since so-called an ou minor utmost in medicine * in the limited "ready" is present: to a Iadlbslastnagen ah. end, l ru eb- dufsr.ns to create. Beyond bj »aets is dis ] R a, dial loaded bsrkeit at dm .C "oks et a1? greed small in comparison tu er" Subläungsg «trained% r er, sometimes with the Crocks et al Irishman he $! T rushed larger Strög the D ruottelit durüh the D = bla & kaxcal required per unit of time, no at all to include ladialbtlartrugen * »d eia larger outer Dracki u to bear even low needle loads; Wed compared t an invention; eetUen read. The purpose of the ind is therefore to be a nater dUendrxok> atohen4een To create floating bearings, glass large radial loads can accommodate , with a relatively low uterar Access pressure is maintained on the warehouse, and where a relatively small amount of pressure medium per unit of time . flows through the camp. En another goal is.t four invention - one mater Außenrruak standing floating bearing $ u create its instability eats to a minimum. It is another object of the Eindung one under external pressure standing floating storage high, speeds and even at temperatures in the Nike freezing point or des Melting points the storage rate, riiale worked satisfactorily A floating bearing m, 03 der under external pressure Erterung ensures a very precise shaft bearing and not jammed when the external pressure fbee the solid exh öh% that is necessary :,. autsuothmen around the radial ventilation. The invention is described below with reference to the drawings. r $ iopiele- * is explained in more detail, namely saigem rfg. 1 an embodiment. der Erftudwmg * in which the . Shaft has a uniform cross-section and the environment is fully developed that the Durchatrbnkal desired between the wilting md their application. sat at; approx. Fig. 2 - a sectional view of the floating bearings according to Fig. 1 # from the end of the shaft to tried to whom no pressure medium through the channels. : wipe the wave and its surroundings -flows; F sharp. 3 shows another embodiment of the invention in which the desired flow channels through training and arrangement of the shaft are created; Fig. 4 a floating camp, similar to the 1n I`ig. 1 ge showed where. the camp near the step .n then gaunt undercut is; sweep a floating agony , i'm the one in Feg. 1 dar-. placed in the one suitable for a warehouse Dimensions shown s fad; sweep 6 is a graph of the pressure drop in FIG lives the storage area, according to feg. 1 shown, strip- Ehenden Iruft, if the whale burdens the dead so dgß never the step area of the storage area: touched i Zig. 7 is a graph showing the pressure test of FIG over the storage area g «ä $ feg. 1 trending Air when the wave eo eahw jim t, dna never of yours The ventilation area of the storage area is properly repaired. In feg. 1 shows almost a housing 1 with a round cross-section , who wears two corpses, 2 and e, who are already eixE right 4 aidhehmen. The two Zager 3 and 3 are priced the pathway inserted into housing 1, 99 ate the 1bdt »rivets between the hagern 2 and and the housing 1 can flow through. Layers ä and 3 are circular objects, and each of them Camp 2 and 3 are on two throughs 5 and 6% sre. 7 and 8 drilled to no two. Mares 9 and 10 to blden v and eaoeeit two r since mares provided storage 1 1 and 12 of which - according to: yet to describe is. The shaft 4 has a slightly lower Diameter 81f e BQhTBdu'ohmesser 596el and 8 the l, ferment 2 and 3. to allow the point 4 to rotate freely and calibrated to move in az i al bend. Camps 2 and 3 are on de both ends of the * hollow Tolle * the housing 1 arranged so that this hollow part partially fills out at each end. Ion Band create a Dr.Qlcraum 13, the s m dheerum of. the overall house 1 and at both sea fitters Tran the lean and ?) limited will. The ' skin 4 extends steadily through the threatening space 13' eia empty 2 $ and beyond this, 1eioh the pressure space, 13 is shown as kreeixr un der Zy liadeer , the anger and the Dineaeiotten this raw rim m e 13 freely selectable. However the distance should v = the deehävx * 1 only real substantially t igr Sder -mein than the distance from the agariläehen 11 are 12 Mac Welk i . Mus Dxuokä = fnnx c 1 4 guide through Gelse 1 and 0, tfaet look at Dmokraus 13. The pae. greßra Dsaob »eaer on snd der» 1ri »13, official rwtahsndde grd14 9 8 * -you only Ehr i. Doorlt eat- a'tt, aesn das di »t% die Dx» icöt ; hta1t u "duroh den. It'lllt '@ ° @ # t @. IMr the netetea of up to 4stt benab wi ebeleils the` it structure on to * 1 mat%! and * red *: obt k ri tie. from jetoll die le, e dtta allo »in a» gaä xW & tg »äfgIiah @ ria.räatr @detn -. xw @ tfi 1 2 ex.o old tsts t what aehäu * 1 should call, it would be necessary that the wool 4 around a The longitudinal axis is symmetrical. But it is not absolutely necessary such d: ß it is designed as a straight, round linder. If there was an axial movement, the shaft 4 only needs to liahen cross-section to quake. Therefore the full one could be 4 babets of the invention have an infinite number of forms. However, the Bearing 2 uaid 3 must be shaped so that the position: surfaces 1 1 and 12 close to. of shaft 4: and so that L1 the contour of the bearing surfaces 1 1 and 12 closely follows the contour of beer wave 4. In Fig. 1 are the Leigerflehen 11 and 12 of. rounder so that the Lgerfläahaa 11 child 12 exactly follow the surface of the shaft 4, where strötrui provided with steps: gskariüla 15 and 16 for the Pressure medium between the shaft 4 and the bearing surfaces 11 and 12 are formed. As illustrated, the stages 9 and 10 ran i.1 ,. close to the outer parts of the bearing surfaces 1 1 and 12, so the furthest from the pressure cavity 13 further away. Share y so that the medium full of the cavity 13 through the channels 15 u-d 16 atrßmend at the end pure path over levels 9 and 10. A part the storage areas 11 and 1 2 will reach the DruaknL.ttel before it hits levels 9 and 10. As levels 9 and 10 , these those parts of the storage areas 11 and 12 denotes the parallel to and above the other part of the bearing surface 11 and 12 lie. 1ta: .e practically @reeigriote working method results-, .3ich, wern- _ - levels 9 and 10 as parts of dUr @af; @: rfli, .ehen. 1 and 12. about a sixth of LaUfrl @chcn 11 and ": take, and if the shaft is centered, A1) r st <, iide z, "" fischeri, of shaft 4 and the IKa; gerfl: .chen 11 uird 12 bei- Bohruri -, - E '-. n 5 and' T etvia doi, i.elt so big are t-.ie the AL: t @ #. @ rid between- four wave 4 uzd the ha; = cr areas 17 and 12 in the diets 6 and B. Weiaa :; I the shaft 4 is in the middle position: so the Strong of Strönfuntskan --- 1e 1--3 and: 6 at levels 9 and 10 about half of the bitch = the remaining parts of the Strcmux.ge_ channels 15 and 16, with air alu pressure r.it tcl it turned out to be V? Tl: @ ti @, K, .inälüt4: rken of about 0.0127 µm , (0.0ß.> 5 inches) around to deny the wave, the far exception of the stages a uräd 10, where the cones 15 and 16 narrowed to about 0.0G655 mm (0, u0025 inches) are. Also, according to FIG. 5, the Z of the Sirömungskan-E.le 15 ui, d 16 1 <4n the axis ier shaft 4 measured "each about 1 the hi-l.fte dea diameter D of the while be 4. The particular dimensions given here are for fragrance particularly suitable as a pressure medium. Due to the @working method this compressed air bearing could within the scope of the invention also any other medium regardless of whether liquid or gaseous is used e also although other dimensions are used 'measured what of the nature of the medium used and the Originally green size of the flow channel 15 and 1 f> depending: ngig is. The ratio L / D can be increased if strömkan, -ile 15 and i6 continue: are. Although the above dimensions and proportions are suitable for an according to invention layer, are after- . standing dimensional ranges and ratios for inventive given bearings: 1. The width of the step - (beislielewii: se 9 or '(0) varies from 1/30 to 1/2 of the width L of the warehouse curses (for example 11 or 12); 2. The clear width Ca in the flow channels (beisriela- way 15, 16; 30 and 32) at the steps (for example e.g. 9, 10, 22 and 23) varies fully 0.3 to 0.9 the clear width Cr in the remaining part of the canals (example 15, 16, 30 and 32); . 3. The length Z of the Durahstrüm canals (for example 151, 169 30 and 32) measured length of the axis of the shaft ? (Beie, iele- 4 and 24) varies from 0.20 bin to 2.0 dte diameter seas D of the wave; 4. The clear width 0e in the Durahtrim canals (such as 15, 16, 30 and 32) varies at the levels (such as 9, 10 * 22 and 4-: 3) from 0900254 up to 0.0508 mm (o.0001 to 0.0020 in) j 5. The clear width C, In the Durohetrömkanölon (as in both $ lielaweise 15, 16, 30 and 32y, who froze the steps (9, 109 22 and 23 ) , red ranges from 0.005-08 to 0.0635. (0.0002 to 0.002.5 inches): To the degree of the pressure center bearing according to fig. 1 . ., _ to explain, is initially only the half of the printing center considered. The medium is under Durek through the Druaküfinung 14 pressed into the pressure chamber 13. from where the medium then flows through the channel 15 and along the step 9 is expressed before the medium is pressed into the pressure chamber 13, the shaft 4 is at rest on paragraph 9. As can be seen * 2, the Contact of the step 9 with the shaft 4 on the lower side of the Wave 4. Fractical, the flow of pressure medium along the lower; 4th side of wool, however . a considerable flow of the Pressure medium held across the shaft 4, due to the large Opening between step 9 and shaft 4 on the upper side of the shaft 4: The pressure medium leaves the pressure chamber 13 and occurs in the Durohstrbmkanal 1 5 with practically the same back over the entire circumference of the entrance of the exhaust port 15; the input is the pressure chamber 1 ,! view the neighboring part. gin pressure drop along the upper side of the shaft 4 takes place two reasons instead. First: on the basis of the well-known phyaikali- shy of law ,. äaß the static pressure decreases when the overall speed of the flow increases # secondly, there is a bungskre.ft, who eatgeger to the Stron the Xedume through the channel 15 stands, where this frictional force with rounding speed of the medium also increases. lut this reason aeibungekraft increases the static pressure along des lanals @ 1-5. However, the channel 15 sa is the lower side the shaft is essentially blocked. Hence the pressure oozes-- medium through the channel 15 along the lower side of the shaft only with*. very slow speed. If the pressure medium "u-: flows along the channel 15, occurs in the channel 15 along- ..: the bottom of shaft 4 only a * very low for two reasons Static pressure drop in consideration of the the aforementioned physical principle takes place, since such a small - 'Flow of the pressure medium along the bottom of the shaft 4 is present is just a small pressure mismatch along the bottom of the Wave 4 and on occurs at the low flow velocity - very little friction. when the pressure medium along the The bottom side of the channel 15 flows. Due to the low friction force there is only a very small loss of pressure. Hence occurs along the bottom of the throughflow channel 15 only a little less Pressure drop from the pressure chamber 13 to the point of the through- flow channels 15 where the stage 9 begins. So it will be a Caused pressure increase along the lower side of the shaft 4 and the disruption of Kräftegleichgewiohtee results eifixe tendency Center shaft 4, i.e. lift off before step 9. When on the shaft 4 is exerted a load that is perpendicular to the. Axis of shaft 4 acts, then d # - shaft 4 approaches step 9 and aims at the Iluß deo pressure medium in the flow - - _, channel 15 near the point where stage 9 of shaft 4 is at next comes, diminish .. Hence occurs in the Muroha flow channel 15 at the point at which -the flow- of the pressure medium in essential, is braked by paragraph 9, an increase on the Druakee. Such an increase in pressure disturbs the Gleiohaewiaht dsr Forces - in the sense of a tendency to move wave 4 from level 9 take off: In this way, wave 4 is constantly in the. Liner surface 11 centered. The right camp 3 practically showed = n the same. 'eise z @ .on shaft 4. The graphic representation fig. b represents the pressure drop over represents the Axrchatrömkanal 15 when air under pressure through the Oftnuni 1 4 is pressed, and when the shaft 4 is loaded so that they to the level 9 @ is present. Curve A shows the pressure = drop in air flow in duct 15 along the bottom of the storage surface 11, where the wave 4 at the step! is present. Curve 3 shows the pressure drop of the air through the duct. 15 along the top Part of the shaft 4 and along the upper part of the bearing surface II e where the-stage 9 furthest from. the shaft 4 is removed. As Curve . shows, there is a very slight drop in pressure before the air reaches level 9, where the pressure is almost very abrupt drops to atmospheric pressure. As curve B shows is however, a nearly uniform pressure drop in the flow-through. Channel 15 available, w the paragraph 9 furthest iron-dsr shaft 4 away. The upper area marked with dagonal lines marked ) represents the on : the shaft 4 actsexade force which is directed to the shaft 4 in the bearing fl = .ohe 11 to center. The lower hatched area ("-" be .z: ichnet) represents a force acting in the vicinity of level 9. which darßu: * is directed, the wave 4 against -the level 9 "- an- to hold lying down. De reaultiorrenäe: power from difference of the upper areaed * + "and dea @""teren area @ -" - "would be aimed to keep the shaft dentred au. , The graphic representation Fig. shows the pressure drop the air flowing through the through-flow channel 15 "when the $ e. through under pressure. the pressure opening 1 4. is pressed in * and when the wave 4 is floating and moving away from the bottom part of the Paragraph 9 has lifted. Curve C shows the pressure drop the air flow 3.n the permeation channel 15 along the bottom of the Storage area 11. The curve j> shows the pressure drop through the foot the through-flow channel 1 5 li.ngs of the upper part of the shaft 4 and along the upper part of the bearing surface 11. The hatched Area in the graph of FIG. 7 represents that of the static pressure of the. Bruckmittel on the shaft 4. exerted force bearing the load from the shaft. In Fig. 3, another contact arm of the invention is shown. posed, in the same components as in Fg. 1 and 3 since are provided with the same reference numerals. The Rmptunter- differentiated between the devices according to h`ig: 1 and 3 exists in that in the device according to FIG. 3, the stages 22 and 23, which have a round cross-section, on a shaft 24 instead on the bearings 2 and 3, as shown in Fig. 1, provided are. Matching bearings 26 and 28, also round transverse sohnitts, are = at the opposite ends of the housing 1 arranged, with the Mger 2E and 28 under preseitz in the Bore of the housing 1 fitted bind so that no leakage of the pressure medium between the housing 1 and the bearings 26 and 28 can take place. There are therefore graded throughflow channels 30 and 32 between the shaft 24 and the corresponding bearings 26 and available. These throughflow channels 34 and 32 'act. practically ... in the same way as the throughflow channels 1 5 and 16 of the Pig: 1. There is therefore no need for further description of the Operation of the device of FIG. 3. fig. FIG. 4 is another embodiment of the invention in turn. refer to the same components with the same references as in Fig. 1 are provided. A camp 44 * similar to the casual one 2 the leig lo, is provided with a circular incision 46 see,. which completely surrounds part of the storage area 1 1 to stage 9 in radial direction stimulated by the flow of the To make pressure medium through the channel 1 5 movable and thereby keep the vibration of the pressure center bearing to a minimum $ ohr @ znken r, The performance according to the invention has various advantages. if for example on Jie Welle according to Pig. 1 'a stick-like loading load is exerted, $ o this can cause the shaft 4 breaks through the print media and, for example, the storage surface 11 touched. Through; ie stage 9 in the through-flow channel 14 the shaft 4 touches the bearing surfaces 1 1 only on the mare 9. Therefore is the wear on a small area of the bearing surface 11 and the wave 4 is limited, Furthermore, the tendency of the wave to touch the steps of the% gerfläol) e 11 by a Vor increase nasty static pressure medium pressure reduced to ` a larger part of the bearing surface 'i 1 acts when the Wella 4 wants to touch the bearing surface 11. This also applies to: the Device of Fig. 3, in which the paragraphs 22 and 23 on the shaft 24 are arranged. Furthermore, the tendency is the Wave "getting stuck" significantly diminished ¢ if-the Shaft only touches the bearing in a small area. Another advantage of the device according to the invention is that the externally pressurized floating Bearing can withstand high badial loads, touching only a relatively small external pressure on the bearing is maintained and while a relatively small amount of pressure medium per time unit flows through the warehouse. Another advantage of the pressure medium bearing according to the invention is it says that it is also effective at extreme temperatures works $ e.g. temperatures close to the freezer point or near the melting point of the storage material. Further advantages of the pressure medium bearing according to the invention are stand in the fact that the associated wave is exactly in the correct position and the bearing does not look stuck if the medium is supplied under greater pressure than is necessary, to bear the badial load resting on the camp. In the case of pressure medium bearings, there have been great difficulties so far Switch off vibrations when operating at very high speeds was working. "This problem was covered in two patents by * Wilc0x 2 683 635 and 2 C8'3 636 dealt with in detail, .d Wilcox found various solutions in which certain hU1tn.vse between the dimensions of the opening, the volume the Druektasahen, the quadrilateral and the cross-sectional area f through which the air must pass, This problem of vibrations occurs in accordance with compressed air bearings practically not on, and it was with your wave with one Durehwesser of 1.59 cm (5/8 inch) speeds of over 80,000 rpm and with a while forward 71.62 cm (3 in.) diameter speeds of "4.fl40 rpm achieved. The difficulties dealt with by '9iloox are due to the Training. Of the new fragrance store switched off. When the wave is at very high speeds within storage indicates # it is possible according to the invention = the air. shut off the supply and the wave In a hydronamic air- to run the film. This was said to be for a purely wave 3 inches in diameter already found at 5,000 F pm. if , the wave revolves, carries thin air films with it. Even crack%. $ it shows a thin film of air * the eggs of the surface the gaunt one remains fixed. At. raised speeds , st the effect of these two passing each other Films .de of a pressure camp. Between the warehouse and the The wave is created in the air, of which the wave and the housing acter keeps touch. This rdrodynamic woman is natüriieb effective only when small forces laterally act on the dent during high radial loads the shaft and the shaft 3: n come into contact. To achieve the effect of the hydrodynamic film , are the dimensions of the space between the bearing and the Wave depending on the medium used and the relative ge speed: the two surfaces also change. At. this- Compressed air storage was a gap of 0.0127 mm (0.0005 inch as shown in Fig. 5: as sufficient for a 7 ', 6 an (3 inch Wave found at a speed of 5,000 rpu. Of the The space under the step of the wave was about half * of 0.0727 or 0.00635 mm (0.005 or 0.0G025 in.). The course is summed up in an Erualrmittellager after the Invention of a pressure medium. unites practically uniform Pressure around the perimeter of the inlet of the IAarchstrom canal between the shaft and the bearing surface on the @ xggrfläeba: The feed pipe and the round hole are sufficiently large, in order to change the airflow across different parts the lagerfläßhe due to lateral movements of the wool nevertheless an approximately even pressure of air outside the oil surface leads. This is in contrast to the various den stand the technology-equivalent with apertured bearings. According to the state of the art, the bearings are marked with veäan Openings the Inft dosed before it reaches the storage area, either through valves in the supply lines or there are are used in such a way that the differences between the Current changes in the ft cause. In contrast, the definition uses a level on the gerfläche or on "the shaft; which itself acts as a valve or oseeiung for the pressure flowing over the bearing surface Means served, ecoch is the Draesel or Vcn hexvoxgexufenl wo = d -. s pressure means over dis gerfläche office. The greatest throttling occurs there = -auf »wexxn the pressure medium flows over the step of the storage area. Äul this way at a Easily obtainable and effective dehydrator storage created. The pressure medium flows over part of the void area with relative- , low Droeselung and streloht over-another part of the gerfläche. with greater mroaselunß. When aidie wave the. Uger: nühert # .mmt die Droeseludes eretobee der Tragerflcpt'he mit der relative @. "Ößeren Zroaaelung_ greater 'yerbtnie au than the''osselung of sharing the casual area xt of the relatively smaller oaaelu Since in. ] Scope of the invention numerous; above kbwandl started the above described. Device for the subject are wanted, dead The invention natürlfoh on any details of the loading wrote enen. .iu.sf`zhzngeformen limited.

Claims (1)

Patent claims before _ Druckm "tte bearing with a one bearing surface for a shaft having bearing, characterized in that the bearing surface is arranged relatively on the shaft in such a way, sat between the shaft and the bearing surface a flow channel for the pressure medium is formed which stretches all around the shaft: where the radial distance in the Durchatrümkanal between the shaft and x ..- the lean over an axially extending area, which runs completely around the shaft, essentially is constant and a value gong between. 0.00508 and 0.0635 to has, so that on the flow of the pressure medium along this Area is exerted a restriction, and sat the radial Gap #: n this through-flow channel: wipe the shaft and the camp läcte, about another. axially the gänzlioh extends around the shaft, in essential diesdr chen kleiräer than- substantially radial exhaust honatane stood Is and within an orbss of between. 0.00254 and 0 "05C18 mm; and further characterized by medium :, nm the flow of the pressure medium to lead this Ibrehetrömkanal " where, in operation: this flow of pressure medium only through the Dereioh of the Durchströmkanaln with im. essential constants - radial distance and finally through the area of the Iürch .-- flow channels with a smaller radial distance flowing through the hindu, whereby pressure differences are created in this flow-through channel r be * and a Treimkreft between the wave .und deiL wr occurs. - Pressure center bearing characterized by a shaft. with a bearing curses provided Uger, whereby the shaft and the IL -: - gerflUahe.so arranged relative to one another and thus formed one that a Murchutrömkansl is formed for the pressure medium, which extends completely around the We_.le, whereby this passage flow channel a first siah axially extending narrowed area having,. who stretches itself completely around the while and with you radial distance between the skin and the surface rrer. can be seen that is essentially constant and one value of between 0, Q05ƒ8 and 0, a655 mm, has: a da8; on the current of the medium along the first area a throttling force is exercised, and a second axially extending ver narrow area that goes all the way around the shaft and the first narrowed area is adjacent and one substantially constant and essentially smaller radial distance between between the shaft and the I, agerfls: che possesses than the radial Distance at this first narrowed area and the e. no Vert of two 0; 00254 and 4.050S mm; and marked draws by means #. to get the flow of the ltediuma to these Durchstrümkanazu directs while working daa Medium first through this narrowed area of the ähxrchström-- channel flows and then through the second narrowed area # so that thereby pressure medium pressure differential in this diameter atrömkanal are created:. and a separation force between the occurs Shaft and the bearing on mm # .. -. Druckeittellager marked by a wanted one with a storage area is arranged so relative to the shaft that a you rehetrö m .. bare for the pressure medium between the lxger and the . Wave is formed, which is completely around. the wave around stretches and wherein the radial gap between the shaft and the storage area via an axially extending lereii'itI, the pace around the wave is essentially constant and sound of a size between f $ 00508 and 0.0635 at slallt Se da £ on your stream the uck, ttels along this draw izel. s stretching area exerted a throttling force aird # and where the radial gap between the shaft and the casual area over another axially extending area, the goes all the way around the shaft, much less than that of the -Bereiak the i u rchströn canal with the constant radial Zacäea a is and has a size of just 08,002.54 and 0.0508 on # "f ernW denoted by a housing that aha Idas casual uni the #tIl! her U ü! augevrdaet lütt, and gekenneeäahnet bh means »a direct the current to the pressure means through nag housing to de * »u rch.- ström " » I suspect an essential oka b fali, where währeled of working the i% dium first through the realm of the duroh. _. . ströt * amle flows ,. the one constant radial twin arm owns, and Schlleglieä. by the Bireahuder a 4ringer having radial clearance ,. whereby olmittelok. " differential In des Da rchatröakanal geeoh & fte * will * 1 y M4 creating a door force between the WW1 and the lagre is produced. , Hydraulic medium bearing characterized by a cylindrical .. gelle g, with a: @ I radially extending paragraph see did! the around the whole: around goes extent of Will further characterized by a bearing with - a cylindrical shaped Dagerfläoha, vsbei this Lagsrtläohe around the shaft a hollow section of the heel is arranged so that a eirümkanal sw see the bearing surface and the shaft is formed, in the Raätale Zwieohenraum *, between 0 "000254 and 0.05ß8 mm places # and the .radial distance in the lurahgirbmkan al in the Bereiohedsr in front of the paragraph and this is adjacent. a _ Word rou has between a, .00588 and ß, 0635 au, so that on the stx-os den olu, ttela , exercised an essential äteali't ,. wirdt and _gekzeiohnet dwcoh N.ttel zum steer des Stnaa- zu dm Durwohnrösksmal ,. oldad: a significant loss of pressure sutirtt # whereby during dun lrbetm the ledium through the 3r »itä desarehsrlwa iltodtg the before the lbsate serve * hsaaehballetzt and # ohliadläoä over 4 «Abeatst, s0 9 l @ "üe kni ttelekdffereutm, t $ n den $ urehetränkatil i # atte »who 4 on, uzt da dursi .eins Tresatt itxinah» der Volle = d- 4 «motor - is effected e i @@ tta @ .eger grlf @ eseiah @ to "@: it oint oyü; @ti7tit @ gtfern% s Volle # a casual as an erestomgrlinäris,, .. foraea-IjoräMrsp dien Rolf is about xnd a second s, yli.noh gtt "sntts l a gertläehep die ebsafalle ' around the shaft and adjacent to the first bearing surface is arranged, the radial distance between the shaft and the first hagerfläohe. between a value of 09.00508 and 0.0635, so that a throttling of the flow of the pressure is effected by means, and the radial Zwisahenrauaa between the Shaft and the second bearing surface substantially less than the radial distance between. the wave and the first Storage area is and within the word of ®, 00254 and Q, 0508 na , whereby a stepped through etrönksnal for the pressure medium between the wool and des stock is stuck and marked euroh smock from - direct the pressure medium flow to this = Murchström » kiu usl a substantial amount of money, whereby during work the Druox means through the Durahaträmraxal, first sw %schen the Full and the first bearing surface and the shaft because swischeu and the second laser surface hindurohflisgt # woduroh Druoi- aftteldruoltdtferatntial: # .n dszr »urohatröaks» l greahat = es and thereby a 2rermkratt = wiash »der Walle% uad tar long appearance. Druolnittella g; he characterized by tim wool p a far from tegeru, the wind snge-grounded around the wave and the eel length of the shaft spaced apart from each other and being one of the casual of the bearing pairs with a first bearing bearing is provided and the other camp of the camp couple lake one: wide 1agerflEehe has and Ue the first reading area raaltiv au des full. is arranged in such a way that a first through- flow channel takes place Druaknitteilager is formed and the second storage area realtirr is arranged to the shaft in such a way " that a second Durohsträmtanal is formed for the pressure medium; whereby. the r diesle Zsohenratim between the shaft and the first bearing surface over an axially extending area of the extends all the way around the shaft, eats and essentially constantly has a value between 0900508 and 0.0635, so: that a - significant throttling exerted on the outflow of the pressure medium becomes and the radial space in the first Du rchatrbiu- - channel between ddteasr shaft td he first bearing surface over another axially extending area " around the wave goes around, much less than the essentially is constant radial clearance and a value wma between. o * 00254 and 090508 has "and the radial space in the" second D xrohströmkane1 between the shaft and the second bearing surface over an axially extending r. # the completely ua "' dU e full goes around # Is 3: m essentially constant and has a value between 0 # 0Q500 and O # 0635 @%, so a substantial throttling on the flow the pressure medium * is exercised and the radial: sohenraun in the. second Durahstriimksnal between the shaft and the second gaunt - area over another see axially extended areas . who goes around the wave # is much less wrong than the latter, substantially constant radial interw. - raun and a value between 0900254 and O, 0508 at the ready # and characterized by Ultteltun . this axial gap between the first gaunt and the second iger too -surrounded so that an iichlra a for receiving the pressure medium and for steering of the pressure medium do the first and the second throughflow @@ kan.i is formed, knowing that a substantial pressure drop will occur. occurs, while this DQhttel only through the 3v 4 * "area of the corresponding MurchströmkanU * with essentially constant radial Zzsehexravn flows and finally through the area of the corresponding Durohström »- channels that have a smaller gap # so da $ Pressure medium pressure ditterentials created in the rcäströmkanUan bep and thereby a separating force between the shaft and the first gaunt as well as between the shaft and the second. l.gtr is formed. '# Dxuckmittellaager characterized by a cylindrically shaped. Shaft with a yaa 'of radially extending shoulders * around the shaft and axially along it- s « are arranged .; also marked artroh one with a first iagerilähe provided * legere the » den ealen riding of the shaft Is # the .one of the .ibeätze of the r Paragraphs with eänzehli $ ß for a first chat room air the pressure center bearing between the shaft and the first gaunt au form ,. in the four radaler.tatohaarrat. @ r3: ewhsxt the one Heel and the lean area of this first 3 series »feehoa 0.254 and 0.050s lies And the radtr.e 4amoheum de ergtex Durehströmkanal des Dryckmittellager, which is in front of the one of the heels is between 0g00506 and 0.065 mm betust; and characterized by a second axially im Distance from this-first 1 lunatic and with a zj lndrisoh shaped bearing surface is provided that around Another axial area of the shaft. -Ordered is "the another paragraph of the pair of paragraphs so that - a second through-flow channel for the. Pressure medium bearings between of the shaft and the second bearing, in which the r: diale . Space between the other landing and the storage area of the second U # 3ger between 0, ®Ü254 and 0.0508 mm and the radial interspace 1 $ i the second DU rc hströmkanal den Pressure bearing core in front of the other paragraph is * between 0; 04508 and 0.0655 , and gskenuzseiohriet. by Middle Umsohließeü of the axial gap swia uhen the first 3 a ger around the second camp = so that there is enough space for the Recording of the pressure medium is formed and means of steering of the pressure means to the first and second rohströncanalt oh »there was an essential pressure drop, whereby while working the pressure medium through jewelet an area , each of the Murohatrßakan, e and then about the corresponding with the first and the second. Abeatt streams connected to the camp, whereby Drual u itteldx u ckdfferentiale in the area each the flow kangle are formed, and thereby a separating force between the shaft and the first as well as swschm of the shaft and the second bearing is formed. B. pressure medium bearing characterized by a shaft, a gaunt with a vain bearing surface, those of the shaft is un georduet at a certain distance, so that in between a through-flow channel i'ür the pressure medium is formed, wherein the space between the bearing surface and the shaft im essentially over a first area of the Darchström Canal * which extends all the way around the shaft and is between mm 0.00508 and constant st, so that an essential Throttling is exerted on the flow of pressure medium, and along the gap between the bearing surface and the shaft of the second area of the through-flow channel, which oich all around the shaft extends, essentially smaller than the first- and a size ven between 0.00254 and 0.0508 mm, means for forming a drouk cavity, the one with the harvested area: the Durehströmkanal in connection stands and wherein the Druokhohlratui is essentially larger than ornamental the first and cyreite areas of the durohat flow canal are, and Means for feeding pressurized Druaknittela into it Pressure cavity, this pressure medium under essentially: constant pressure remains in the pressure cavity and through the first and second area of the Ihzrchströmkanala flows to Pressure medium pressure editing tisle in the flow cannulas and create a separating force between the lame and the gaunt to create.